Abraham Stroock

Abraham Stroock
Nationality	American
Alma mater	Harvard University (PhD, 2002), Pierre and Marie Curie University (MS, 1997), Cornell University (BS, 1995)
Scientific career
Fields	Chemical and Biomolecular Engineering
Institutions	Cornell University
Doctoral advisor	George M. Whitesides

Abraham D. Stroock is an American academic and chemical engineer known for his contributions to microfluidics technologies used in cell and molecular biology, tissue engineering, and In vivo measurements. He holds the Gordon L. Dibble '50 Professorship at Smith School of Chemical and Biomolecular Engineering ^[1] and is an adjunct professor in the School of Integrative Plant Science at Cornell University. He is the principal investigator and director of CROPPS. ^[2] In 2022, Stroock was elected as a fellow of the American Association for the Advancement of Science. ^[3]

Education and career

Stroock received his Bachelor of Science degree in Physics from Cornell University in 1995. ^[4] Following graduation, he worked in the research division of Electricite de France and in 1997 completed a master's degree ^[5] at the University of Paris VI and XI in Solid State Physics. He returned to the United States to pursue graduate studies at Harvard University, where he earned his Ph.D. in Chemical Physics in 2002 under the supervision of George M. Whitesides. ^[6]

After completing his Ph.D., Stroock joined the faculty at Cornell University in 2003. He was promoted to associate professor in 2009 and full professor in 2015, when he was named the Gordon L. Dibble '50 Professor of Chemical Engineering. At the Smith School of Chemical and Biomolecular Engineering at Cornell, he has served as school director ^[7] from 2016-2021.

Stroock has been involved in executive positions at several Cornell initiatives dedicated to driving scientific advancements through the development of tools and infrastructure to explore, characterize and innovate across the nanoscale and agricultural domains. Since 2010 he has served on the executive committees of the Cornell Nanoscale Facility ^[8] and from 2018-2021 served as associate director for the Cornell Institute for Digital Agriculture. ^[9]

Research

Stroock's research interests lie at the intersection of engineering and biology. ^[10] He has made contributions ^[11] to the field of microfluidics, developing techniques for manipulating fluids on a small scale. His work has applications in various fields, including biomedical research, ^[12] agriculture ^[13] and environmental monitoring. ^[14]

His graduate research ^[15] at Harvard focused on the development of microfluidic platforms for studying biological systems, particularly focusing on understanding the behavior of cells and tissues in complex environments. At Cornell, Stroock’s research ^[16] explores how to manipulate transport dynamics and chemical processes at micrometer scales in both natural and synthetic systems. His work is particularly focused on understanding and engineering microvascular processes in mammals ^[17] and plants. ^[18]

Stroock leads research ^[19] that includes studying and applying plant-inspired mechanisms for liquid manipulation, investigating properties of liquid water under negative pressure, exploring biophysical processes governing vascular development for tissue engineering and conducting theoretical, numerical, and experimental studies of fluid mechanics at small scales for chemical processes.

Plant Biology

Stroock’s work in plant biology has focused on experiments and modeling related to vascular function and drought stress physiology. He contributed seminal research ^[20] replicating how plants move water from roots to leaves using the cohesion-tension process in an artificial device. In 2014, he published a detailed mathematical model of the coupled thermal and mass transfer processes in leaves ^[21] and microelectromechanical device for continuous measurements of stem water potential. ^[22] He has published research on plant physiology and water dynamics, including multi-scale mathematical model into localized measurements of water potential, ^[23] microfluidic model of symplastic phloem loading ^[24] and a non-disruptive nanoreporter of local water in leaves. ^[25] His lab developed a microelectromechanical system ^[26] (MEMS)-based tensiometer, a microtensiometer that allows for in-plant, continuous measurement of stem water potential. FloraPulse Co. ^[27] has commercialized this technology for use in a variety of crops and has sales to growers and scientists around the world.

AquaDust

The Stroock lab developed AquaDust, ^[28] which uses nanoscale sensors and fiber optics to measure water status inside the leaf of a plant. This material ^[29] consists of tiny hydrogel particles embedded with fluorescent dyes that respond to water stress and reports the water potential of the air-space near the mesophyll. AquaDust has applications in agricultural settings to monitor soil moisture and optimize irrigation.

Center for Research on Programmable Plant Systems

Stroock became director and principal investigator of the Center for Research on Programmable Plant Systems (CROPPS) ^[30] in 2022 after serving as co-PI with Susan McCouch since the inception of CROPPS in 2021. CROPPS is a collaborative research initiative that focuses on the convergence of plant physiology, advanced engineering, computer science and social science to understand and manipulate plant systems at a fundamental level. ^[31]

References

1. "Abraham D. Stroock". Cornell Engineering.
2. "Center for Research on Programmable Plant Systems (CROPPS)". Center for Research on Programmable Plant Systems.
3. "2022 AAAS Fellows". American Association for the Advancement of Science.
4. "Abraham D. Stroock". Cornell Engineering.
5. "Learn More About Cornell Engineering". Cornell Engineering, Cornell University.
6. "Whitesides Research Group Alumni". Harvard University.
7. "How industry engineers are changing the classroom". pp. Cornell Engineering, Cornell University.
8. "Cornell NanoScale Facility (CNF) Executive Committee". Cornell NanoScale Facility.
9. "Leadership". Cornell Institute for Digital Agriculture.
10. "Abraham D. Stroock". Cornell Engineering, Cornell University.
11. "Plant Biophysics and Engineering". Stroock Group.
12. Ju, Anne (May 16, 2011). "Artificial tissue promotes skin growth in wounds". pp. Cornell Chronicle.
13. "#68: Solved: The Mystery of Gravity-Defying Sap One synthetic tree accomplishes what loads of scientists never could". Discover Magazine .
14. "The Mysterious Motion of Water in Plants". pp. The Kavli Foundation.
15. "Whitesides Research Group". Harvard University.
16. Fleischman, Tom. "Twelve faculty members elected AAAS fellows". Cornell Chronicle .
17. Choi, Nak Won; Cabodi, Mario; Held, Brittany; Gleghorn, Jason P.; Bonassar, Lawrence J.; Stroock, Abraham D. (2007). "Microfluidic scaffolds for tissue engineering". Nature Materials . 6 (11): 908–915. Bibcode:2007NatMa...6..908C. doi:10.1038/nmat2022. PMID   17906630.
18. Zheng, Ying; Chen, Junmei; Craven, Michael; Choi, Nak Won; Totorica, Samuel; Diaz-Santana, Anthony; Kermani, Pouneh; Hempstead, Barbara; Fischbach-Teschl, Claudia; López, José A.; Stroock, Abraham D. (2012). "In vitro microvessels for the study of angiogenesis and thrombosis". Proceedings of the National Academy of Sciences . 109 (24): 9342–9347. Bibcode:2012PNAS..109.9342Z. doi: 10.1073/pnas.1201240109 . PMC   3386137 . PMID   22645376.
19. "Plant Biophysics and Engineering". Stroock Group.
20. Pagay, Vinay; Santiago, Michael; Sessoms, David A.; Huber, Erik J.; Vincent, Olivier; Pharkya, Amit; Corso, Thomas N.; Lakso, Alan N.; Stroock, Abraham D. (2014). "A microtensiometer capable of measuring water potentials below −10 MPa". Lab on a Chip . 14 (15): 2806–2817. doi:10.1039/C4LC00342J. PMID   24901287.
21. Rockwell, Fulton Ewing; Holbrook, N. Michele; Stroock, Abraham Duncan (2014). "The Competition between Liquid and Vapor Transport in Transpiring Leaves". Plant Physiology . 164 (4): 1741–1758. doi:10.1104/pp.114.236323. PMC   3982738 . PMID   24572172.
22. Pagay, Vinay; Santiago, Michael; Sessoms, David A.; Huber, Erik J.; Vincent, Olivier; Pharkya, Amit; Corso, Thomas N.; Lakso, Alan N.; Stroock, Abraham D. (2014). "A microtensiometer capable of measuring water potentials below −10 MPa". Lab on a Chip . 14 (15): 2806–2817. doi:10.1039/C4LC00342J. PMID   24901287.
23. Jain, Piyush; Huber, Annika E.; Rockwell, Fulton E.; Sen, Sabyasachi; Holbrook, Noel Michele; Stroock, Abraham D. (2024). "Localized measurements of water potential reveal large loss of conductance in living tissues of maize leaves". Plant Physiology . 194 (4): 2288–2300. doi:10.1093/plphys/kiad679. PMC   10980393 . PMID   38128552.
24. Comtet, Jean; Jensen, Kaare H.; Turgeon, Robert; Stroock, Abraham D.; Hosoi, A. E. (2017). "Passive phloem loading and long-distance transport in a synthetic tree-on-a-chip". Nature Plants . 3 (4): 17032. arXiv: 1709.06145 . Bibcode:2017NatPl...317032C. doi:10.1038/nplants.2017.32. hdl:1721.1/101330. PMID   28319082.
25. Jain, Piyush; Liu, Weizhen; Zhu, Siyu; Chang, Christine Yao-Yun; Melkonian, Jeff; Rockwell, Fulton E.; Pauli, Duke; Sun, Ying; Zipfel, Warren R.; Holbrook, N. Michele; Riha, Susan Jean; Gore, Michael A.; Stroock, Abraham D. (2021). "A minimally disruptive method for measuring water potential in planta using hydrogel nanoreporters". Proceedings of the National Academy of Sciences . 118 (23). Bibcode:2021PNAS..11808276J. doi: 10.1073/pnas.2008276118 . PMC   8201978 . PMID   34074748.
26. "Chip detects water needs: Microsensors implanted in tree trunks or vines can measure water stress directly". Good Fruit Grower .
27. "FloraPulse".
28. "Nanoscale sensors measure elusive water levels in leaves". Cornell Chronicle.
29. Ramanujan, Krishna. "Water sensor moves from basic research to promising business". Cornell Chronicle .
30. "Center for Research on Programmable Plant Systems". Cornell University.
31. "$25M center will use digital tools to 'communicate' with plants". Cornell Chronicle .